RU2259532C1 - Valve mechanism for dosed feed of gas of pneumatic gas cylinder weapon - Google Patents

Abstract

FIELD: pneumatic weapon, in particular, valve mechanisms for dosed feed of gas of multi-charged gas cylinder weapon shooting by bullets of various shape and other propellant components.

SUBSTANCE: the mechanism has a body with a gas-escape channel connected through prick needle to the gas cylinder, seat installed in the rear part of the body, valve positioned inside the body in the gas chamber for movement along the body and made in the form of a hollow cylindrical gas vent with a rod, which through a hole projects from the seat for engagement with the weapon hammer at a shot, spring fitted onto the valve and providing the return of the valve to the closed state.

EFFECT: reduced loss of gas and enhanced reliability of mechanism operation.

13 cl, 11 dwg

Description

The invention relates to the field of pneumatic weapons, and in particular to valve mechanisms for the dosed gas supply of multiply charged gas-cylinder weapons, firing bullets of various shapes and other missile elements.

Known valve mechanism for the dosed gas supply of pneumatic gas weapon described in patent RU No. 2151357, class. F 41 B 11/06, 2000. The mechanism has a housing, at the base of which there is a gas channel connecting through a puncture needle to a gas spray, a valve that is a hollow cylinder and installed inside the housing in a gas chamber with the ability to move along the housing, a spring, dressed on the valve and resting on one side on the front wall of the body, and on the other hand on the conical expansion of the valve, and providing the valve to return to the closed state after a portion of gas from the gas chamber enters the bullet channel of the weapon barrel, with DLO a threaded nut, housed in the rear part of the housing, and a rod disposed within the seat and forming part of the valve.

A portion of the gas from the gas chamber into the valve enters in this mechanism through openings made at an angle to the axis of the valve. The manufacture of such holes involves the use of precise technological equipment for boring inclined holes, which leads to a rise in the cost of manufacturing the mechanism. At the time of the shot, with the valve open, a portion of the gas first enters the cavity located between the bullet channel of the weapon barrel and the end side of the valve body. Because of this, the gas pressure drops, which leads to a decrease in the initial velocity of the bullet.

The closest analogue is the valve mechanism for the dosed gas supply of pneumatic gas-balloon weapons, described in patent RU No. 2205344, class. F 41 B 11/00, 2003. The mechanism has a body, at the base of which there is a gas channel connecting through a puncture needle to a gas spray, a valve in the form of a hollow cylinder with a conical extension, in which gas holes are installed, installed inside the body in a gas chamber with the ability to move along the body, the spring, dressed on the valve and resting on one side on a plate mounted on the front wall of the body, and on the other hand on the conical expansion of the valve, and ensuring the valve returns to the closed state after a portion of gas is received from the gas chamber through the gas holes in the bullet channel of the barrel of the weapon, a seat located in the rear of the body and a rod located inside the seat and which is an integral part of the valve.

A portion of the gas from the gas chamber into the valve here, as well as in the previous mechanism, enters through openings made at an angle to the axis of the valve. The manufacture of such holes involves the use of precise technological equipment for boring inclined holes, which leads to a rise in the cost of manufacturing the mechanism.

In this design of the valve mechanism, the seat is rigidly fixed in the housing, which eliminates the possibility of axial movement of the seat along the axis of the valve, i.e. the volume of the gas chamber always remains constant.

The basis of the invention is the task of creating a valve mechanism for the dosed gas supply of pneumatic gas-filled weapons with such structural elements and their connections that would improve the operational characteristics of the weapon by regulating the gas flow and reduce its losses, improve the manufacturability of the structure, by combining a mechanical seal into a common assembly and valve mechanism.

This problem was solved by creating a valve mechanism for the metered gas supply of pneumatic gas-balloon weapons containing a housing, at the base of which there is a gas-duct connected through a puncture needle to a gas spray, a saddle made in the form of a cup and installed with a threaded connection in the back of the housing with the bottom outward with axial movement, a valve installed inside the housing in the gas chamber with the ability to move along the housing and made on the one hand in the form of a hollow cylinder of a natural gas duct providing gas from the gas chamber through gas openings in the gas duct and the front wall of the body to the bullet channel of the weapon barrel when the valve is open, and on the other hand in the form of a rod that protrudes from the saddle through the hole in the bottom of the saddle to interact with the gun trigger when fired, a spring located inside the gas chamber and providing the valve to return to the closed state after a portion of gas from the gas chamber enters the bullet channel of the weapon barrel, while the spring is dressed on the valve gas duct and positioned between the front wall of the housing and the flange on the valve.

At the exit of the gas channel into the gas chamber in the wall of the housing there is a recess, due to which a constant flow of gas from the gas spray into the gas chamber of the housing is provided.

The part of the cylindrical valve gas duct located between the stem and the flange and in which there are gas holes is made with flats. Inside the saddle at the bottom there is a cylindrical recess, the transverse dimension of which is greater than the transverse dimension of the part of the cylindrical gas duct made with flats. Such constructive solutions allow, by increasing the internal volume of the hull without increasing its dimensions, to increase the portion of gas flowing through the valve into the bullet channel of the gun barrel during firing, which in turn increases the initial speed of the bullet.

The possibility of axial movement of the seat by screwing it into the casing or unscrewing it from the casing while maintaining the tightness of the valve mechanism allows you to change the volume of the gas chamber, i.e. vary the initial velocity of the bullet when fired.

A valve sleeve is installed inside the seat, and is in contact with the side of the flange when the valve is closed. Between the housing and the seat in the annular groove located on the side of the seat in contact with the housing, a seal ring is placed. The flange of the valve, the end contacting with the spring, has the shape of a truncated cone, tapering to a rod, the transverse dimension of which is smaller than the transverse size of the cylindrical gas duct. In this case, the side of the flange has a hemispherical shape. An end seal is installed in the hole in the front wall of the housing, the sealing flange of which is located on the inside of the front wall of the housing. In this case, the end seal is made of elastic material. Between the flange of the mechanical seal and the spring there is a guide ring, a sealing ring and a washer. Such design solutions can reduce gas leaks.

On the outside of the front wall of the housing there is a protrusion, on the lower and side walls of which there are chamfers.

In the side walls of the base of the body there are holes for pins attaching the body to the weapon body.

The drawings show an example embodiment of the invention, which depicts:

figure 1 - weapon, side view;

figure 2 - weapon, front view;

figure 3 is a fragment of a section 1-1 in figure 2, the valve is closed;

figure 4 is a fragment of a section 1-1 in figure 2, the valve is open;

figure 5 - case, General view from the back;

6 is a housing, a General front view;

Fig.7 is a valve, side view;

Fig.8 is a valve, a General front view;

Fig.9 - valve, General rear view;

figure 10 - end seal, General view;

11 is an end seal, side view.

The valve mechanism for the dosed gas supply of pneumatic gas balloon weapons (Figs. 1-4), made according to the invention, comprises a housing 1 (Figs. 5-6), a valve 2, a seat 3 and a spring 4.

The saddle 3 is made in the form of a cup and, with a threaded connection, is installed in the rear part of the housing 1 with the bottom 5 facing outward, so that the housing 1 and the saddle 3 form a closed container - a gas chamber 6. The volume of the gas chamber 6 can be changed by screwing the saddle 3 into the housing 1 or unscrewing it from the housing 1 without loss of tightness of the valve mechanism. At the base 7 of the housing 1 there is a gas channel 8, connected through a puncture needle 9 with a gas spray 10. At the exit of the gas channel 8 into the gas chamber 6, there is a recess 11 in the wall of the housing 1, which ensures a constant flow of gas from the gas spray 10 into the gas camera 6.

The valve 2 is placed inside the housing 1 in the gas chamber 6 coaxially with the bullet channel 12 of the barrel of the weapon and can move along the housing 1. The valve 2 (Fig.7-9) on the one hand is made in the form of a hollow cylindrical gas duct 13, through which the gas comes from the gas the chamber 6 through the gas holes 14 in the gas duct 13 and the hole 15 in the front wall 16 of the housing 1 into the bullet channel 12 of the weapon barrel when the valve 2 is open, and on the other hand in the form of a rod 17, which protrudes from the hole 18 in the bottom 5 of the saddle 3 saddles 3 for interaction with the trigger 19 weapons when fired. A flange 20 is located on the valve 2 in its middle part. The part of the gas duct 13, which has gas holes 14, located between the stem 17 and the flange 20, is made with flats 21. The flange 20 of the valve 2 has the shape of a truncated cone, tapering to the stem 17, the transverse dimension which is smaller than the transverse size of the gas duct 13. The lateral side 22 of the flange 20 has a hemispherical shape.

In the bottom 5, on the inner side of the seat 3 there is a cylindrical recess 23, the transverse dimension of which is greater than the transverse dimension of the part of the gas duct 13 made with flats 21, which allows to increase the volume of gas in the gas chamber 6 without increasing the size of the housing 1, due to the placement in the recess 23 of the rod 17 and part of the gas duct 13 having gas holes 14. At the bottom 5 of the seat 3 is installed a cuff 24 in contact with the side 22 of the flange 20 when the valve 2 is closed. The hemispherical shape of the side 22 of the flange 20, in contact with the cuff 24, almost completely eliminates the leakage of gas from the gas chamber 6 into the bullet channel 12 of the weapon barrel when the valve 2 is closed. In the annular groove 25 located on the side of the seat 3 in contact with the housing 1, a seal ring 26 is placed between the housing 1 and the seat 3.

The spring 4 is dressed on the gas duct 13 of the valve 2 and is located in the gas chamber between the front wall 16 of the housing 1 and the end face 27 of the flange 20. The spring 4 provides a preliminary compression of the valve 2 to the cuff 24 when the gas cartridge 10 is punctured and the valve 2 returns to the closed state after a portion arrives gas from the gas chamber 6 to the bullet channel 12 of the gun barrel.

An end coaxial seal 28 is installed in the hole 15 in the front wall 16 of the housing 1 (FIGS. 10-11), the sealing flange 29 of which is located on the inner side 30 of the front wall 16 of the housing 1. The seal 28 is made of elastic material. Between the flange 29 of the seal 28 and the spring 4, a guide ring 31, a seal ring 32, and a washer 33 are located.

On the outer side 34 of the front wall 16 of the housing 1 is a protrusion 35, on the lower and side walls of which there are chamfers 36.

At the base 7 of the housing 1 there are holes 37 for fastening with pins 38 of the housing 1 to the housing 39 of the weapon.

The mechanism works as follows.

After the needle 9 punctures the gas cartridge 10, gas constantly flows through the gas channel 8 located at the base 7 and the recess 11 in the wall of the housing 1 into the gas chamber 6.

Before firing the cock 19 cocked (figure 3). The spring 4 is in the released state and presses on the end 27 of the flange 20 of the valve 2. The flange 20 is pressed with its hemispherical side to the cuff 24 and the gas does not enter the gas-outlet openings 14 so that the gas chamber 6 is blocked. Stem 17 protrudes from seat 3. Valve 2 is closed.

At the time of the shot, the trigger 19 hits the stem 17 (Fig. 4), the valve 2, moving towards the barrel of the weapon, opens, the spring 4 is compressed, a gap appears between the flange 20 and the cuff 24. Gas from the gas chamber 6 through the gas orifice 14 and the gas duct 13 enters the bullet channel 12 of the barrel of the weapon. Under the pressure of a portion of gas, the bullet 40 flies out of the barrel, a shot occurs, while the gas is kept from spurious leakage by the seal 28.

Immediately after the shot, the trigger 19 returns to its initial position, the spring 4 unclenches, the flange 20 is pressed against the cuff 24 and blocks the gas from entering the gas duct 13 of valve 2. Valve 2 is again closed.

The invention can be easily made from modern materials based on existing technology and can most effectively be used in the manufacture of multi-charged gas balloon weapons for firing bullets of various shapes and other missile elements.

Claims (13)

1. Valve mechanism for the dosed gas supply of pneumatic gas-balloon weapons, comprising a housing, at the base of which there is a gas channel connecting through a puncture needle to a gas canister, a seat installed in the rear of the housing, a valve located inside the housing in the gas chamber with the possibility of movement along the housing and made in the form of a hollow cylindrical gas duct with a rod that protrudes through the hole from the saddle to interact with the trigger of the weapon when fired, a spring worn on the valve and providing moiety return valve in the closed state, characterized in that the seat is a cup-shaped bottom outwardly, axially movable relative to the housing portion gazovoda located between the stem and the flange present on the gazovode is formed with flats in which there are gas holes. 2. The mechanism according to claim 1, characterized in that there is a cylindrical recess in the bottom of the seat to accommodate the part of the gas duct having flats when the valve is closed, the transverse dimension of which is smaller than the transverse size of the recess. 3. The mechanism according to claim 1 or 2, characterized in that a cuff is installed inside the seat, which is in contact with the side of the flange when the valve is closed. 4. The mechanism according to claim 1, characterized in that between the body and the seat in the annular groove located on the side of the seat in contact with the body, a seal ring is placed. 5. The mechanism according to claim 1, characterized in that the valve flange, the end face in contact with the spring, has the shape of a truncated cone, tapering to a rod, the transverse dimension of which is less than the transverse size of the gas duct. 6. The mechanism according to claim 5, characterized in that the side of the flange has a hemispherical shape. 7. The mechanism according to claim 1, characterized in that in the place of exit of the gas channel into the gas chamber in the wall of the housing there is a recess. 8. The mechanism according to claim 1, characterized in that in the hole in the front wall of the housing is installed end coaxial seal, the sealing flange of which is located on the inner side of the front wall of the housing. 9. The mechanism of claim 8, wherein the end coaxial seal is made of elastic material. 10. The mechanism of claim 8, characterized in that between the flange of the end coaxial seal and the spring there is a guide ring, a sealing ring and a washer. 11. The mechanism according to claim 1, characterized in that on the outside of the front wall of the housing there is a protrusion. 12. The mechanism according to claim 11, characterized in that there are chamfers on the lower and side walls of the protrusion. 13. The mechanism according to claim 1, characterized in that in the side walls of the base of the housing there are holes for the pins of the housing to the weapon body.

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